U.S. patent number 7,867,115 [Application Number 11/957,904] was granted by the patent office on 2011-01-11 for segmented ball with lighted elements.
This patent grant is currently assigned to Tangle, Inc.. Invention is credited to Richard E. Zawitz.
United States Patent |
7,867,115 |
Zawitz |
January 11, 2011 |
Segmented ball with lighted elements
Abstract
Embodiments of the instant invention include lighted bounceable
toys for play and amusement. Such toys or structures can be made in
an infinite number of graceful and useful configurations. Exemplary
bounceable ball toys include a light assembly having a power source
and a plurality of light emitting elements, and a spherical
skeletal structure having a plurality of segments. The spherical
skeletal structure defines an open interior cavity, and at least
some segments of the skeletal structure include a channel opening
that faces toward the interior cavity. Light emitting elements
transmit light to the channel openings.
Inventors: |
Zawitz; Richard E. (South San
Francisco, CA) |
Assignee: |
Tangle, Inc. (San Francisco,
CA)
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Family
ID: |
40753886 |
Appl.
No.: |
11/957,904 |
Filed: |
December 17, 2007 |
Prior Publication Data
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Document
Identifier |
Publication Date |
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US 20090156092 A1 |
Jun 18, 2009 |
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Current U.S.
Class: |
473/570; 446/175;
446/438; 446/439; 473/612 |
Current CPC
Class: |
A63B
43/06 (20130101); A63H 33/22 (20130101); A63H
33/18 (20130101); A63B 39/00 (20130101) |
Current International
Class: |
A63B
37/00 (20060101) |
Field of
Search: |
;473/570,571,612
;446/91,175,438,439 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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2503780 |
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May 1976 |
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DE |
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1195407 |
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Jun 1959 |
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FR |
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2259257 |
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Mar 1993 |
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GB |
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Primary Examiner: Kim; Gene
Assistant Examiner: Baldori; Joseph B
Attorney, Agent or Firm: Townsend and Townsend and Crew
LLP
Claims
What is claimed is:
1. A bounceable ball toy, comprising: a light assembly having a
power source and a plurality of light emitting diodes; a first end
cap; a second end cap; and a spherical skeletal structure having a
plurality of curved loop segments which form a continuous loop, the
spherical skeletal structure defining an open interior cavity and
having a first end and a second end, wherein each curved loop
segment has a curved end and an opposite end, wherein the curved
end of each loop segment is coupled with the first end cap at the
first end of the spherical skeletal structure, wherein the opposite
end of each loop segment is coupled with the second end cap at the
second end of the spherical skeletal structure, wherein at least
some segments of the skeletal structure comprise a channel opening
that faces toward the interior cavity, wherein the light assembly
extends between adjacent skeletal structure segment channels, and
wherein the light emitting diodes are disposed at least partially
within the channel openings.
2. The bounceable ball toy of claim 1, wherein the spherical
skeletal structure defines at least two apertures that provide
fluid communication between the open interior cavity and an ambient
space disposed outside of an external boundary defined by the
skeletal structure.
3. The bounceable ball toy of claim 1, wherein the light assembly
is configured to direct light toward a surface of the channel
opening.
4. The bounceable ball toy of claim 1, wherein at least some of the
segments comprise a portion that is transparent or translucent to
light.
5. The bounceable ball toy of claim 1, wherein the light assembly
comprises a wire that is disposed at least partially within the
channel openings.
6. A bounceable ball toy, comprising: a light assembly; and a
skeletal structure having a plurality of curved loop segments which
collectively form a single continuous loop, the skeletal structure
defining an open interior cavity and having a first end and a
second end, wherein each curved loop segment has a curved end and
an opposite end, wherein the curved end of each loop segment meets
at the first end of the skeletal structure without intersecting,
wherein the opposite end of each loop segment meets at the second
end of the skeletal structure without intersecting, wherein the
single continuous loop of the skeletal structure provides a single
continuous non-intersecting central longitudinal axis extending
coaxially within each of the curved loop segments, wherein at least
some segments of the skeletal structure comprise a channel opening
that faces toward the interior cavity, wherein the light assembly
extends between adjacent skeletal structure segment channels, and
wherein the light assembly is disposed at least partially within
the channel openings.
7. A toy, comprising: a light assembly; and a skeletal structure
having a curved loop segment that forms a single continuous loop,
the skeletal structure defining an open interior cavity and having
a first end and a second end, wherein the curved loop segment has
at least three curved ends and at least three opposite ends,
wherein each curved end of the loop segment meets at the first end
of the skeletal structure without intersecting, wherein each
opposite end of the loop segment meets at the second end of the
skeletal structure without intersecting, wherein at least some
segments of the skeletal structure comprise a channel opening that
faces toward the interior cavity, wherein the light assembly
extends between adjacent skeletal structure segment channels, and
wherein the light assembly is disposed at least partially within
the channel openings.
8. The toy of claim 7, wherein the light assembly comprises a light
emitting diode or a glowstick.
9. The toy of claim 7, wherein the skeletal structure defines two
or more apertures that provide fluid communication between the open
interior cavity and an ambient space disposed outside of an
external boundary defined by the skeletal structure.
10. The toy of claim 7, wherein the skeletal structure defines a
shape selected from the group consisting of a sphere, a spheroid, a
prolate spheroid, an oblate spheroid, an ellipsoid, a toroid, and a
geodesic sphere.
11. The toy of claim 7, wherein the light assembly comprises a
processor.
12. The toy of claim 7, wherein the skeletal structure is coupled
with a logo plate comprising a filter or an aperture.
13. The toy of claim 7, wherein the skeletal structure comprises a
thermoplastic resin having a durometer of about 60.
Description
CROSS-REFERENCES TO RELATED APPLICATIONS
This application is related to U.S. Pat. Nos. 4,509,929, 5,110,315,
and 6,086,445, and U.S. patent application Ser. Nos. 10/744,962
filed Dec. 23, 2003, 11/015,387 filed Dec. 16, 2004, 11/152,020
filed Jun. 13, 2005, and 11/558,350 filed Nov. 9, 2006, the entire
contents of each of which are incorporated herein by reference.
BACKGROUND OF THE INVENTION
Embodiments of the invention relate generally to the field of toys,
and in particular to devices and methods that involve lighted
segments having curved or angular profiles. Embodiments of the
present invention provide toys or objects for use as balls,
therapeutic instruments, baby toys, pet toys, beach or pool rafts,
and the like.
The incorporation of lighted features has provided the basis for a
variety of toys and other useful objects. Although such toys and
objects have been generally commercially successful, it would be
desirable to provide certain innovations and diversifying features.
For these and other reasons, there continues to be a need for
improved toy systems and other useful and decorative structures.
Embodiments disclosed herein provide solutions to such needs.
BRIEF SUMMARY OF THE INVENTION
Embodiments of the instant invention address these and other
unfulfilled needs by providing systems, devices, and methods
involving toys with lighted segments, which provide appealing
stimulation to the visual and tactile senses. Such toys or
structures can be made in an infinite number of graceful and
decorative configurations. Moreover, these objects can function as
bounceable, rollable, throwable, inflatable, or floatable devices,
as diversion tranquilizers for occupying a user's hands and
attention, and as toys for general amusement and artistic
inspiration.
In one aspect, embodiments of the present invention include a
bounceable ball toy. The toy includes a light assembly having a
power source and a plurality of light emitting diodes. The toy also
includes a spherical skeletal structure having a plurality of
segments, where the spherical skeletal structure defining an open
interior cavity. At least some segments of the skeletal structure
have a channel opening that faces toward the interior cavity. The
light emitting diodes are disposed at least partially within the
channel openings. In some cases the spherical skeletal structure
defines at least two apertures that provide fluid communication
between the open interior cavity and an ambient space disposed
outside of an external boundary defined by the skeletal structure.
The light assembly may be configured to direct light toward a
surface of the channel opening. In some cases, at least some of the
segments have a portion that is transparent or translucent to
light. Optionally, the light assembly includes a wire that is
disposed at least partially within the channel openings.
In another aspect, embodiments of the present invention encompass a
bounceable ball toy that includes a light assembly and a skeletal
structure. The skeletal structure may include a plurality of
segments, and may define an open interior cavity. In some cases,
one or more segments of the skeletal structure include a support.
The light assembly can be configured to direct light into the
supports. A support may include a channel, a lumen, a bulb, a tube,
a passage, or the like. In some cases, a support includes a channel
having a concave surface that faces toward the open interior
cavity. In related cases, the light assembly is configured to
direct light toward the concave surface of the channel. Optionally,
the support may include a lumen, and the light assembly can have a
light emitting element disposed within the lumen.
In still another aspect, embodiments of the present invention
include a toy having a light assembly and a skeletal structure. The
skeletal structure can have at least one segment, and can define an
open interior cavity. The light assembly can be configured to
direct light into at least one segment of the skeletal structure or
into a core module disposed at least partially within the skeletal
structure. In some cases, the light assembly includes a light
emitting diode or a glowstick. In some cases, a segment or core
module includes a channel, and the light assembly includes a light
emitting diode or a glowstick configured to direct light toward or
through a surface of the channel. Optionally, a segment or core
module can have a lumen, and the light assembly can have a light
emitting diode configured to direct light toward or through a
surface of the lumen. The skeletal structure may define two or more
apertures that provide fluid communication between the open
interior cavity and an ambient space disposed outside of an
external boundary defined by the skeletal structure. The skeletal
structure may also define a shape such as a sphere, a spheroid, a
prolate spheroid, an oblate spheroid, an ellipsoid, a toroid, a
geodesic sphere, or the like. In some cases, a light assembly may
include a processor. In some cases, the skeletal structure may be
coupled with a logo plate. The logo plate can include a filter, an
aperture, or any of a variety of translucent, transparent, or
opaque components or materials. In some embodiments, a core module
may have one or more struts. Optionally, a core module may include
a platform. In some cases, a skeletal structure includes a
thermoplastic resin having a durometer of about 60.
In yet another aspect, embodiments of the present invention
encompass a method of making a bounceable ball toy. An exemplary
method may include coupling a power source holder with a plurality
of light emitting diodes to form a light assembly, and coupling the
light assembly with a spherical skeletal structure having a
plurality of segments. At least some segments of the skeletal
structure may have a channel opening that faces toward an open
interior cavity defined by the skeletal structure. A light emitting
diode may be disposed at least partially within a channel opening.
The method may also include placing a power source in operative
association with the power source holder. In some methods, a
skeletal structure segment may include a material that is
transparent or translucent to light. In some methods, a power
source holder can be attached with a skeletal structure
segment.
According to some aspects, embodiments of the present invention
include a method of making a toy that includes, for example,
providing a light assembly, and coupling the light assembly with a
skeletal structure. The skeletal structure may define an open
interior cavity. In some methods, the skeletal structure defines
two or more apertures that provide fluid communication between the
open interior cavity and an ambient space disposed outside of an
external boundary defined by the skeletal structure. In some
methods, the skeletal structure includes a channel facing toward
the open interior cavity, and the light assembly is configured to
direct light toward the channel. Optionally, the skeletal structure
may include a lumen, and the light assembly can be configured to
illuminate an interior space of the lumen. In some methods, the
skeletal structure includes a portion that is transparent or
translucent to light. According to certain method embodiments, the
light assembly includes a glowstick, or a power source holder
having connectivity with a plurality of light emitting
elements.
For a fuller understanding of the nature and advantages of the
present invention, reference should be had to the ensuing detailed
description taken in conjunction with the accompanying
drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 illustrates a perspective view of a toy according to
embodiments of the present invention.
FIG. 2 illustrates an exploded perspective view of a toy according
to embodiments of the present invention.
FIG. 3 illustrates an exploded perspective view of a toy according
to embodiments of the present invention.
FIG. 4 illustrates a perspective view of a toy according to
embodiments of the present invention.
FIGS. 5 to 5E show aspects of a toy according to embodiments of the
present invention.
FIG. 6 illustrates a perspective view of a toy according to
embodiments of the present invention.
FIG. 7 illustrates a perspective view of a toy according to
embodiments of the present invention.
FIG. 8 illustrates a perspective view of a toy according to
embodiments of the present invention.
FIG. 9 illustrates a perspective view of a toy according to
embodiments of the present invention.
FIG. 10 illustrates a perspective view of a toy according to
embodiments of the present invention
FIGS. 11 to 11B show aspects of a toy according to embodiments of
the present invention.
FIGS. 12 to 12B show aspects of a toy according to embodiments of
the present invention.
FIGS. 13 to 13B show aspects of a toy according to embodiments of
the present invention.
FIG. 14 shows aspects of a toy according to embodiments of the
present invention.
FIGS. 15A-1 and 15A-2 show aspects of a toy according to
embodiments of the present invention.
FIGS. 15B-1 and 15B-2 show aspects of a toy according to
embodiments of the present invention.
FIGS. 15C-1 and 15C-2 show aspects of a toy according to
embodiments of the present invention.
FIGS. 16A and 16B show aspects of toys according to embodiments of
the present invention.
DETAILED DESCRIPTION OF THE INVENTION
Turning now to the drawings, FIG. 1 illustrates a perspective view
of a toy according to embodiments of the present invention. Toy 100
includes a skeletal structure 110 having a plurality of segments
120. Skeletal structure 110 defines an open interior cavity 130.
Typically, open interior cavity 130 is in fluid communication with
an ambient space or environment 160 disposed outside of the toy. As
such, at some locations the segments themselves may provide a
separation or boundary between interior cavity 130 and ambient
space 160, whereas in other places there may be no physical barrier
between the cavity and the ambient space. Hence, in some
embodiments it may be helpful to describe a boundary envelope 150
that corresponds to, and in some cases is defined by, the skeletal
structure. Boundary envelope 150 can have a shape similar to that
of the skeletal structure. As shown in FIG. 1, boundary envelope
150 can have a generally spherical shape that corresponds to the
spherical shape outline of skeletal structure 110. In a geometric
sense, boundary envelope 150 can define an outer limit of open
interior cavity 130, particularly in locations there is no physical
separation between the interior cavity and the ambient space
provided by the skeletal structure itself. Optionally, open
interior cavity 130 may be in fluid communication with ambient
space 160 via a plurality of apertures 112 which are defined by
skeletal structure 110. Segments 120 can have supports 122 such as
channels or lumens. As shown here, toy 100 also includes a light
assembly 140 having a power source 142 and a plurality of light
emitting diodes (LEDs) 144. Light assembly 140 includes a wire or
conducting element 146 that conducts electricity between power
source 142 and LEDs 144. Light assembly 140 can be configured to
direct light 148 into a plurality of supports 122.
As shown in FIG. 1A, a toy operator 10a can throw a toy 100a toward
a surface 101a. As toy 100a strikes surface 101a, the toy or
portions thereof can elastically deform or deflect such that the
toy subsequently bounces. FIG. 1B depicts an elastic deflection
102b of one or more segments of a toy 100b as it contacts or
collides with surface 101b. Similarly, a user can hold the toy in
their hand, and deform the toy by applying a compressive force. The
application of force by the user provides strengthening for the
hand and finger muscles as well as rehabilitation for the joints.
Simultaneously, the operator may enjoy the visual display provided
by the lighting assembly of the toy. One or more segments of the
toy can be coated with any of a variety of materials. The coatings
on the segments may be any type of color, may include translucent
or transparent material, and may have a variety of thicknesses,
textures, durometers, compression deflection pressures, and the
like. Merely by way of example, the thickness of the coating may be
in the range from about 1 mm to about 6 mm, and more preferably
from about 2 mm to about 4 mm. Examples of textures that may be
used include dots, detents, dimples, lines, roughened, smooth,
sticky, and the like.
FIG. 2 illustrates an exploded perspective view of a toy according
to embodiments of the present invention. Toy 200 includes a
skeletal structure 210 having a plurality of segments 220. Skeletal
structure 210 defines an open interior cavity 230. In some
embodiments, open interior cavity 230 is in fluid communication
with an ambient space 260 disposed at the outside of the toy.
Optionally, open interior cavity 230 may be in fluid communication
with ambient space 260 via a plurality of apertures 212 defined by
skeletal structure 210. Segments 220 can have supports 222 such as
channels or lumens. As shown here, toy 200 also includes a light
assembly 240 having a power source 242 and a plurality of light
emitting diodes (LEDs) 244. Light assembly 240 also includes a wire
246 that conducts electricity between power source 242 and LEDs
244. Light assembly 240 can be configured to direct light 248 into
a plurality of supports 222.
As shown here, skeletal structure 210 can be constructed from a
first portion 214 and a second portion 216. These portions may be
coupled together in any of a variety of ways. For example, first
portion 214 can include a plurality of posts 215, and second
portion 216 can include a plurality of receptacles 217 that are
adapted to receive posts 215. In the embodiment depicted here,
first portion 214 and second portion 216 represent two
hemispherical components, which form skeletal structure 210 when
coupled together.
FIG. 3 illustrates an exploded perspective view of a toy according
to embodiments of the present invention. Toy 300 includes a
skeletal structure 310 having a plurality of segments 320. Skeletal
structure 310 defines an open interior cavity 330. In some
embodiments, open interior cavity 330 is in fluid communication
with an ambient space 360 disposed outside of the toy. Optionally,
open interior cavity 330 may be in fluid communication with ambient
space 360 via a plurality of apertures 312 defined by skeletal
structure 310. Segments 320 can have supports 322 such as channels
or lumens. In some cases, one or more segments may not include a
support. Toy 300 also includes a light assembly 340. Optionally,
light assembly may include a power source 342. Light assembly 340
includes one or more light emitting elements 344. In some cases,
light emitting element 344 may include a light emitting diode
(LED), an organic light emitting diode (OLED), or the like.
Similarly, light emitting element may include a fluorescent or
incandescent light. A light emitting element may emit light
radiation at any of a variety of wavelengths. For example, a light
emitting element may emit infrared, visible, or ultraviolet light.
Light assembly 340 also includes one or more wires 346 that conduct
electricity between power source 342 and light emitting element
344.
As shown here, skeletal structure 310 can be constructed from a
first portion 314 and a second portion 316. These portions may be
coupled together in any of a variety of ways. For example, first
portion 314 can include a plurality of posts 315, and second
portion 316 can include a plurality of receptacles 317 that are
adapted to receive posts 315. In some embodiments, first portion
314 and second portion 316 represent two hemispherical components,
which form skeletal structure 310 when coupled together. Toy 300
also includes a platform 370 configured to support or hold light
assembly 340. Platform 370 can be coupled with skeletal structure
310 as desired. For example, platform 370 can include a plurality
of apertures 372 which are adapted to receive posts 315
therethrough. Light assembly 340 can be configured to direct light
348 into a plurality of supports 322. As noted elsewhere herein,
supports 322 can include channels or lumens.
FIG. 4 illustrates a perspective view of a toy according to
embodiments of the present invention. Toy 400 includes a skeletal
structure 410 having a single segment 420. In this sense, skeletal
structure 410 may present a unitary or monolithic structure.
Skeletal structure 410 defines an open interior cavity 430. In some
embodiments, open interior cavity 430 is in fluid communication
with an ambient space 460 disposed outside of the toy. Optionally,
open interior cavity 430 may be in fluid communication with ambient
space 460 via one or more apertures 412 which are defined by
skeletal structure 410. Segment 420 can have one or more supports
422 such as channels or lumens. As shown here, toy 400 also
includes a light assembly 440. Optionally, light assembly may
include a power source 442. Light assembly 440 includes one or more
light emitting elements 444. Light assembly 440 can be configured
to direct light 448 into one or more supports 422.
FIG. 5 shows a portion of a toy according to embodiments of the
present invention. Toy 500 includes a skeletal structure 510 having
a segment 520. As shown here, segment 520 includes a channel 522
that can receive light 548 emitted from a light assembly 540. FIG.
5A shows a cross-section of a skeletal structure segment 520a of a
toy, according to embodiments of the present invention. The toy
includes a light emitting element 544a disposed at least partially
within a channel 522a of segment 520a. Light emitting element 544a
is configured to illuminate channel 522a with light 548a. In some
cases, light 548a is reflected from the surface of segment 520a, as
indicated by arrow A. In some cases, light 548a is transmitted
through segment 520a. For example, light 548a can be transmitted
through segment 520a, as indicated by arrow B. Light reflecting and
transmitting properties of segment 520a may depend on the material
used to construct the segment. For example, segment 520a or a
portion thereof may include a reflective surface material, such as
a mirror, which reflects light. Similarly, segment 520a or a
portion thereof may include a transparent material such as glass,
or a translucent material such as frosted glass, which allows light
to pass therethrough. Segment 520a can be configured to provide
light reflection or transmission, in either a diffuse or specular
fashion. In some cases, segment 520a or a portion thereof may
include an opaque material, through which light cannot pass. FIG.
5B shows a cross-section of a skeletal structure segment 520b of a
toy, according to embodiments of the present invention. The toy
includes a light emitting element 544b disposed outside of channel
522b. Light emitting element 544b is configured to illuminate
channel 522b with light 548b. In some cases, light 548b is
reflected from the surface of segment 520b, as indicated by arrow
A. In some cases, light 548b is transmitted through segment 520b.
For example, light 548b can be transmitted through segment 520b, as
indicated by arrow B. Light reflecting and transmitting properties
of segment 520b may depend on the material used to construct the
segment. For example, segment 520b or a portion thereof may include
a reflective surface material, such as a mirror, which reflects
light. Similarly, segment 520b or a portion thereof may include a
transparent material such as glass, or a translucent material such
as frosted glass, which allows light to pass therethrough. Segment
520b can be configured to provide light reflection or transmission,
in either a diffuse or specular fashion. In some cases, segment
520b or a portion thereof may include an opaque material, through
which light cannot pass. FIG. 5C shows a cross-section of a
skeletal structure segment 520c of a toy, according to embodiments
of the present invention. Segment 520c presents a tubular or closed
configuration. The toy includes a light emitting element 544c
disposed within a lumen 522c. Light emitting element 544c is
configured to illuminate channel 522c with light 548c. Light 548c
is transmitted through segment 520c. For example, light 548c can be
transmitted through segment 520c, as indicated by arrow B. Light
transmitting properties of segment 520c may depend on the material
used to construct the segment. For example, segment 520c or a
portion thereof may include a transparent material such as glass,
or a translucent material such as frosted glass, which allows light
to pass therethrough. Segment 520c can be configured to provide
light transmission, in either a diffuse or specular fashion. In
some cases, segment 520c or a portion thereof may include an opaque
material, through which light cannot pass. As shown in FIG. 5D, in
some embodiments a light emitting element 544d or another portion
of a light assembly can be directly coupled with or adjacent to
segment 520d. For example, light emitting element 544d can be
attached with a segment surface 521d of segment 520d that is
disposed within channel 522d. FIG. 5E shows a similar construction,
where light emitting element 544e is attached with or adjacent to a
segment surface 521e of segment 520e, where segment surface 521e is
disposed within lumen 522e.
In addition to the shapes depicted in FIGS. 1-4, embodiments of the
present invention provide skeletal structures having generally
spherical shapes in other desired or useful configurations. FIG. 6
illustrates a perspective view of a toy according to embodiments of
the present invention. The toy includes looped or bent segments,
such as those described in U.S. patent application Ser. No.
11/558,350 filed Nov. 9, 2006, the contents of which are
incorporated herein by reference. Toy 600 includes a skeletal
structure 610 having one or more segments 620. Skeletal structure
610 defines an open interior cavity 630. In some embodiments, open
interior cavity 630 is in fluid communication with an ambient space
660 disposed outside of the toy. Optionally, open interior cavity
630 may be in fluid communication with ambient space 660 via one or
more apertures 612 which are defined by skeletal structure 610.
Segment 620 can have one or more supports 622 such as channels or
lumens. As shown here, toy 600 also includes a light assembly 640.
Optionally, light assembly may include a power source 642. Light
assembly 640 includes one or more light emitting elements 644.
Light assembly 640 can be configured to direct light 648 into one
or more supports 622. Wire 646 can conduct electricity from power
source 642 to light emitting elements 644.
FIG. 7 illustrates a perspective view of a toy according to
embodiments of the present invention. Toy 700 includes a skeletal
structure 710 having one or more segments 720. Toy 700 can provide
a soccer ball type of shape or construction. Skeletal structure 710
defines an open interior cavity 730. In some embodiments, open
interior cavity 730 is in fluid communication with an ambient space
760 disposed outside of the toy. Optionally, open interior cavity
730 may be in fluid communication with ambient space 760 via one or
more apertures 712 which are defined by skeletal structure 710.
Segment 720 can have one or more supports 722 such as channels or
lumens. As shown here, toy 700 also includes a light assembly 740.
Optionally, light assembly may include a power source 742. Light
assembly 740 includes one or more light emitting elements 744.
Light assembly 740 can be configured to direct light 748 into one
or more supports 722. Wire 746 can conduct electricity from power
source 742 to light emitting elements 744.
FIG. 8 illustrates a perspective view of a toy according to
embodiments of the present invention. Toy 800 can provide a
continuous weave type of shape or construction. Toy 800 includes a
skeletal structure 810 having one or more segments 820. Skeletal
structure 810 defines an open interior cavity 830. In some
embodiments, open interior cavity 830 is in fluid communication
with an ambient space 860 disposed outside of the toy. Optionally,
open interior cavity 830 may be in fluid communication with ambient
space 860 via one or more apertures 812 which are defined by
skeletal structure 810. Segment 820 can have one or more supports
822 such as channels or lumens. As shown here, toy 800 also
includes a light assembly 840. Optionally, light assembly may
include a power source 842. Light assembly 840 includes one or more
light emitting elements 844. Light assembly 840 can be configured
to direct light 848 into one or more supports 822. Wire 846 can
conduct electricity from power source 842 to light emitting
elements 844.
FIG. 9 illustrates a perspective view of a toy according to
embodiments of the present invention. Toy 900 can provide a
pentagon type of shape or construction. Toy 900 includes a skeletal
structure 910 having one or more segments 920. Skeletal structure
910 defines an open interior cavity 930. In some embodiments, open
interior cavity 930 is in fluid communication with an ambient space
960 disposed outside of the toy. Optionally, open interior cavity
930 may be in fluid communication with ambient space 960 via one or
more apertures 912 which are defined by skeletal structure 910.
Segment 920 can have one or more supports 922 such as channels or
lumens. As shown here, toy 900 also includes a light assembly 940.
Optionally, light assembly may include a power source 942. Light
assembly 940 includes one or more light emitting elements 944.
Light assembly 940 can be configured to direct light 948 into one
or more supports 922. Wire 946 can conduct electricity from power
source 942 to light emitting elements 944.
FIG. 10 illustrates a perspective view of a toy according to
embodiments of the present invention. Toy 1000 can provide a
football type of shape or construction, configured to present a
lighted message. Toy 1000 includes a skeletal structure 1010 having
one or more segments 1020. Skeletal structure 1010 defines an open
interior cavity 1030. In some embodiments, open interior cavity
1030 is in fluid communication with an ambient space 1060 disposed
outside of the toy. Optionally, open interior cavity 1030 may be in
fluid communication with ambient space 1060 via one or more
apertures 1012 which are defined by skeletal structure 1010.
Segment 1020 can have one or more supports 1022 such as channels or
lumens. As shown here, toy 1000 also includes a light assembly
1040. Optionally, light assembly may include a power source 1042.
Light assembly 1040 includes one or more light emitting elements
1044. Light assembly 1040 can be configured to direct light 1048
into one or more supports 1022. Wire 1046 can conduct electricity
from power source 1042 to light emitting elements 1044. Toy 1000
may also include a processor 1007 coupled with or integrated into
lighting assembly 1040. Processor 1007 can be configured to
activate and deactivate light emitting elements 1044 as desired.
For example, processor 1007 can be configured to activate and
deactivate light emitting elements 1004 in a sequence so that toy
1000 presents a lighted text message or other pattern when toy 1000
spins or rotates about an axis 1008 as indicated by arrow A, such
as when toy 1000 it thrown by a toy user.
FIG. 11 illustrates an exploded perspective view of a toy according
to embodiments of the present invention. Toy 1100 includes a
skeletal structure 1110 having a plurality of segments 1120.
Skeletal structure 1110 defines an open interior cavity 1130. In
some embodiments, open interior cavity 1130 is in fluid
communication with an ambient space 1160 disposed outside of the
toy. Optionally, open interior cavity 1130 may be in fluid
communication with ambient space 1160 via a plurality of apertures
1112 defined by skeletal structure 1110. Segments 1120 can have
supports 1122 such as channels or lumens. In some cases, one or
more segments may not include a support. Toy 1100 also includes a
light assembly 1140. Optionally, light assembly may include a power
source 1142, such as one or more button cell batteries, and a PC
board or processor 1107 which contains a tangible medium embodying
machine-readable code for controlling activation of the light
emitting elements. Light assembly 1140 includes one or more light
emitting elements 1144 that emit light 1148. In some cases, light
emitting element 1144 may include a light emitting diode (LED), an
organic light emitting diode (OLED), or the like. Similarly, light
emitting element may include a fluorescent or incandescent light. A
light emitting element may emit light radiation at any of a variety
of wavelengths. For example, a light emitting element may emit
infrared, visible, or ultraviolet light. Light assembly 1140 may
also includes one or more wires that conduct electricity between
power source 1142 and light emitting element 1144.
As shown here, skeletal structure 1110 can be constructed from a
first portion 1114 and a second portion 1116. These portions may be
coupled together in any of a variety of ways. For example, first
portion 1114 can include a plurality of receptacles 1115, and
second portion 1116 can include a plurality of posts 1117 that are
adapted to insert into receptacles 1115. In some embodiments, first
portion 1114 and second portion 1116 represent two components,
which form a skeletal structure 1110 having a prolate spheroid
shape, such as an American football shape, when coupled together.
As shown here, toy 1100 can also include end caps 1103 and a logo
plate 1104 which can be coupled with skeletal structure 1110. Toy
1100 also includes a platform 1170 configured to support or hold
light assembly 1140. Platform 1170 can include supports 1122 such
as channels or lumens. Platform 1170 can be coupled with skeletal
structure 1110 as desired. For example, platform 1170 can include
one or more struts 1171 that attach with skeletal structure 1110.
Optionally, struts 1171 may include one or more apertures 1172
which are adapted to receive posts 1117 therethrough. In some
cases, a platform can be constructed of one or more pieces. For
example, platform 1170 is depicted here as a composite structure
that includes platform top bracket 1170i and platform bottom
bracket 1170ii. As shown in FIG. 11A, a light emitting element
1144a can be disposed within, or positioned to direct light 1148a
into, a support 1122a such as a channel or lumen of a platform
1170a. Light emitting element 1144a can also transmit light 1148a
into or toward a support 1122a such as a channel or lumen of a
strut 1171a. For example, support 1122a of platform 1170a can
transmit light 1148a, as indicated by arrow A, and supports 1122a
of struts 1171a can transmit light 1148a, as indicated by arrows B.
Light emitting element 1144a can also direct or project light as
indicated by arrow C beyond a support 1122a, platform 1170a, or
struts 1171a, toward or onto a skeletal structure, or toward or
onto or through a logo panel or plate associated with the
structure, or through an aperture in a skeletal structure toward an
ambient space or environment. In some cases, a light emitting
element 1144b can be disposed within, and configured to direct
light 1148b into, a support 1122b such as a channel or lumen of a
strut 1171b, as shown in FIG. 11B. Relatedly, light emitting
element 1144b can be disposed within support 1122b of strut 1171b,
and configured to direct or transmit light toward or within support
1122b of platform 1170b. For example, support 1122b of platform
1170b can transmit light 1148b, as indicated by arrow A, and
supports 1122b of struts 1171b can transmit light 1148b, as
indicated by arrows B. Light emitting element 1144b can also direct
or project light as indicated by arrow C beyond a support 1122b,
platform 1170b, or struts 1171b, toward or onto a skeletal
structure, or through an aperture in a skeletal structure toward an
ambient space or environment.
FIG. 12 illustrates an exploded perspective view of a toy according
to embodiments of the present invention. Toy 1200 includes a
skeletal structure 1210 having a plurality of segments 1220.
Skeletal structure 1210 defines an open interior cavity 1230. In
some embodiments, open interior cavity 1230 is in fluid
communication with an ambient space 1260 disposed outside of the
toy. Optionally, open interior cavity 1230 may be in fluid
communication with ambient space 1260 via a plurality of apertures
1212 defined by skeletal structure 1210. Segments 1220 can have
supports 1222 such as channels or lumens. In some cases, one or
more segments may not include a support. Toy 1200 also includes a
light assembly 1240. Optionally, light assembly may include a power
source 1242, such as one or more button cell batteries, and a PC
board or processor 1207 which contains a tangible medium embodying
machine-readable code for controlling activation of the light
emitting elements. Light assembly 1240 includes one or more light
emitting elements 1244 that emit light 1248. In some cases, light
emitting element 1244 may include a light emitting diode (LED), an
organic light emitting diode (OLED), or the like. Similarly, light
emitting element may include a fluorescent or incandescent light. A
light emitting element may emit light radiation at any of a variety
of wavelengths. For example, a light emitting element may emit
infrared, visible, or ultraviolet light. Light assembly 1240 may
also includes one or more wires that conduct electricity between
power source 1242 and light emitting element 1244.
As shown here, skeletal structure 1210 can be constructed from a
first portion 1214 and a second portion 1216. These portions may be
coupled together in any of a variety of ways. For example, first
portion 1214 can include a plurality of receptacles 1215, and
second portion 1216 can include a plurality of posts 1217 that are
adapted to insert into receptacles 1215. In some embodiments, first
portion 1214 and second portion 1216 represent two generally
hemigeodesic or semigeodesic components, which form a skeletal
structure 1210 having a geodesic shape when coupled together. Toy
1200 also includes a platform 1270 configured to support or hold
light assembly 1240. As shown here, platform 1270 can include a
removable cap 1273, such as a snap lid. Platform 1270 can include
supports 1222 such as channels or lumens. Platform 1270 can be
coupled with skeletal structure 1210 as desired. For example,
platform 1270 can include one or more struts 1271 that attach with
skeletal structure 1210. Optionally, struts 1271 may include one or
more apertures 1272 which are adapted to receive posts 1217
therethrough. In some cases, a platform can be constructed of one
or more pieces. For example, platform 1270 is depicted here as a
composite structure that includes platform top bracket 1270i and
platform bottom bracket 1270ii. As shown in FIG. 12A, a light
emitting element 1244a can be disposed within, or positioned to
direct light 1248a into, a support 1222a such as a channel or lumen
of a platform 1270a. Light emitting element 1244a can also transmit
light 1248a into or toward a support 1222a such as a channel or
lumen of a strut 1271a. For example, support 1222a of platform
1270a can transmit light 1248a, as indicated by arrow A, and
supports 1222a of struts 1271a can transmit light 1248a, as
indicated by arrows B. Light emitting element 1244a can also direct
or project light as indicated by arrow C beyond a support 1222a,
platform 1270a, or struts 1271a, toward or onto a skeletal
structure, or through an aperture in a skeletal structure toward an
ambient space or environment. In some cases, a light emitting
element 1244b can be disposed within, and configured to direct
light 1248b into, a support 1222b such as a channel or lumen of a
strut 1271b, as shown in FIG. 12B. Relatedly, light emitting
element 1244b can be disposed within support 1222b of strut 1271b,
and configured to direct or transmit light toward or within support
1222b of platform 1270b. For example, support 1222b of platform
1270b can transmit light 1248b, as indicated by arrow A, and
supports 1222b of struts 1271b can transmit light 1248b, as
indicated by arrows B. Light emitting element 1244b can also direct
or project light as indicated by arrow C beyond a support 1222b,
platform 1270b, or struts 1271b, toward or onto a skeletal
structure, or through an aperture in a skeletal structure toward an
ambient space or environment.
FIG. 13 illustrates an exploded perspective view of a toy according
to embodiments of the present invention. Toy 1300 includes a
skeletal structure 1310 having a plurality of segments 1320.
Skeletal structure 1310 defines an open interior cavity 1330. In
some embodiments, open interior cavity 1330 is in fluid
communication with an ambient space 1360 disposed outside of the
toy. Optionally, open interior cavity 1330 may be in fluid
communication with ambient space 1360 via a plurality of apertures
1312 defined by skeletal structure 1310. Segments 1320 can have
supports 1322 such as channels or lumens. In some cases, one or
more segments may not include a support. Toy 1300 also includes a
light assembly 1340. As shown here, light assembly 1340 can include
one or more light emitting elements 1344 that emit light 1348.
Light emitting element 1344 may include, for example, a glowstick
or lightstick. Such light emitting elements typically include
chemicals that are capable of producing light through
chemoluminescence. An exemplary glowstick includes an outer plastic
tube that holds a fluorescent dye, a derivate of phenyl oxalate
ester, and an inner breakable glass vial containing hydrogen
peroxide. In use, an operator can bend the outer plastic tube which
in turn breaks the inner vial, thus allowing the hydrogen peroxide
to react with the phenyl oxalate ester. Energy released from this
reaction excites the dye, and the excited dye releases light. The
color of the emitted light is determined by the dye structure. A
glowstick can have any desired shape.
As shown here, skeletal structure 1310 can be constructed from a
first portion 1314 and a second portion 1316. These portions may be
coupled together in any of a variety of ways. For example, first
portion 1314 can include a plurality of receptacles 1315, and
second portion 1316 can include a plurality of posts 1317 that are
adapted to insert into receptacles 1315. In some embodiments, first
portion 1314 and second portion 1316 represent two generally
hemigeodesic or semigeodesic components, which form a skeletal
structure 1310 having a geodesic shape when coupled together. Toy
1300 also includes a platform 1370 configured to support or hold
light assembly 1340. As shown here, platform 1370 can include a
removable cap 1373, such as a snap lid. Platform 1370 can include
supports 1322 such as channels or lumens. Platform 1370 can be
coupled with skeletal structure 1310 as desired. For example,
platform 1370 can include one or more struts 1371 that attach with
skeletal structure 1310. Optionally, struts 1371 may include one or
more apertures 1372 which are adapted to receive posts 1317
therethrough. In some cases, a platform can be constructed of one
or more pieces. For example, platform 1370 is depicted here as a
composite structure that includes platform top bracket 1370i and
platform bottom bracket 1370ii. As shown in FIG. 13A, a light
emitting element 1344a can be disposed within, or positioned to
direct light 1348a into, a support 1322a such as a channel or lumen
of a platform 1370a. Light emitting element 1344a can also transmit
light 1348a into or toward a support 1322a such as a channel or
lumen of a strut 1371a. For example, support 1322a of platform
1370a can transmit light 1348a, as indicated by arrow A, and
supports 1322a of struts 1371a can transmit light 1348a, as
indicated by arrows B. Light emitting element 1344a can also direct
or project light as indicated by arrow C beyond a support 1322a,
platform 1370a, or struts 1371a, toward or onto a skeletal
structure, or through an aperture in a skeletal structure toward an
ambient space or environment. In some cases, a light emitting
element 1344b can be disposed within, and configured to direct
light 1348b into, a support 1322b such as a channel or lumen of a
strut 1371b, as shown in FIG. 13B. Relatedly, light emitting
element 1344b can be disposed within support 1322b of strut 1371b,
and configured to direct or transmit light toward or within support
1322b of platform 1370b. For example, support 1322b of platform
1370b can transmit light 1348b, as indicated by arrow A, and
supports 1322b of struts 1371b can transmit light 1348b, as
indicated by arrows B. Light emitting element 1344b can also direct
or project light as indicated by arrow C beyond a support 1322b,
platform 1370b, or struts 1371b, toward or onto a skeletal
structure, or through an aperture in a skeletal structure toward an
ambient space or environment.
FIG. 14 illustrates additional features of a core module or
interior support module, according to embodiments of the present
invention. Toy 1400 includes a skeletal structure 1410 coupled with
a core module 1490. As shown here, core module 1490 includes a
platform 1470 and a plurality of struts 1471. Struts 1471 can be
configured in any of a variety of three dimensional orientations.
For example, a first strut may be aligned along a X-axis, a second
strut may be aligned along a Y-axis, and a third strut may be
aligned along a Z-axis. A strut can impart tensile strength to a
skeletal structure. Skeletal structure 1410, core module platform
1470, core module strut 1471, or any combination thereof, may
include one or more supports 1422 such as channels or lumens. In
some cases, a strut support may be in continuous communication with
a skeletal structure support, so that light transmitted through the
strut support can travel into the skeletal structure support, and
light transmitted through the skeletal structure support can travel
into the strut support. Core module 1490 can be coupled with
skeletal structure 1470, such that a first strut 1471i of core
module 1490 is coupled with skeletal structure 1470 at a first
location 1471a, and a second strut 1471ii of core module 1490 is
coupled with skeletal structure 1470 at a second location 1471b.
First location 1471a and second location 1471b can be connected by
a line 1473, such that the line represents a chord. As shown here,
such a line or chord passes through the interior of the skeletal
structure.
Skeletal structure 1410 of toy 1400 defines an open interior cavity
1430. Typically, open interior cavity 1430 is in fluid
communication with an ambient space or environment 1460 disposed
outside of the toy. As such, at some locations the skeletal
structure itself may provide a separation or boundary between
interior cavity 1430 and ambient space 1460, whereas in other
places there may be no physical barrier provided by the skeletal
structure between the cavity and the ambient space. Optionally,
open interior cavity 1430 may be in fluid communication with
ambient space 1460 via a plurality of apertures 1412 which are
defined by skeletal structure 1410. Skeletal structure 1410 can
have supports 1422 such as channels or lumens. As shown here, toy
1400 also includes a light assembly 1440 having a power source 1442
and a plurality of light emitting diodes (LEDs) 1444. Light
assembly 1440 includes a wire or conducting element 1446 that
conducts electricity between power source 1442 and LEDs 1444. Light
assembly 1440 can be configured to direct light 1448 into a
plurality of supports 1422.
In some embodiments, one or more struts 1471 may include an
accordion configuration. As depicted here, a strut 1471 may include
an inner segment 1471c, an outer segment 1471d, and a housing
segment 1471e disposed between the inner and outer segments. In
some cases, housing segment 1471 can be configured to house a light
emitting element. Struts and housing elements may also include
supports such as lumens, channels, passages, and the like,
configured to house or contain various components of a light
assembly, including light emitting elements, wires, processors,
energy source holders, energy sources, and the like.
FIG. 15A-1 illustrates a toy according to embodiments of the
present invention. Toy 1500a includes a skeletal structure 1510a
having a plurality of segments 1520a. Skeletal structure 1510a
defines an open interior cavity 1530a. In some embodiments, open
interior cavity 1530a is in fluid communication with an ambient
space 1560a disposed outside of the toy. Optionally, open interior
cavity 1530a may be in fluid communication with ambient space 1560a
via a plurality of apertures 1512a defined by skeletal structure
1510a. Segments 1520a can have supports 1522a such as channels or
lumens. In some cases, one or more segments may not include a
support. Toy 1500a also includes a light assembly 1540a.
Optionally, light assembly may include a power source 1542a, such
as one or more button cell batteries, and a PC board or processor
1507a which contains a tangible medium embodying machine-readable
code for controlling activation of the light emitting elements.
Light assembly 1540a includes one or more light emitting elements
1544a that emit light 1548a. In some cases, light emitting element
1544a may include a light emitting diode (LED), an organic light
emitting diode (OLED), or the like. Similarly, light emitting
element may include a fluorescent or incandescent light. A light
emitting element may emit light radiation at any of a variety of
wavelengths. For example, a light emitting element may emit
infrared, visible, or ultraviolet light. Light assembly 1540a may
also includes one or more wires that conduct electricity between
power source 1542a and light emitting element 1544a.
Skeletal structure 1510a can present a prolate spheroid shape, such
as an American football shape. Toy 1500a can also include end caps
1503a and a logo plate 1504a which can be coupled with skeletal
structure 1510a. Toy 1500a also includes a light assembly 1540a
that can transmit light toward, onto, or through supports 1522a
such as channels or lumens. Toy 1500a may also include platform and
strut assemblies, as described elsewhere herein. As shown here,
logo plate 1504a includes a contour 1504a' and a plurality of
apertures 1504a'', and is configured to present a shaped outline,
template, or silhouette of a logo or other graphic element. The
logo or other graphic element can represent any of a variety of
companies, brand names, groups, projects, persons, organizations,
or any other desired organization, item, devices, process, or the
like. As shown here, the combination of the contour and apertures
can provide a stylized type, either alone or in conjunction with a
graphic representation. Toy 1500a is configured so that light
transmitted from or emitted by various light emitting elements can
pass through apertures 1504a'', or along the outer edges of contour
1504a'. In this way, toy 1500a can present a variety of light
presentations to an toy operator or user, or to any observer. For
example, light passing through apertures 1504a'' can provide or
present one or more light beams, where the shape of each light beam
corresponds to the shape of the individual aperture though which
that beam passes, so as to present a toy operator with an image of
the word "TANGLE". Optionally, logo plate 1504a can include
supports within the body 1504a''' of the logo plate, and the
supports can transmit light in such a way that light emitted from
the body 1504a''' presents a toy operator with an inverse image of
the word "TANGLE". FIG. 15A-2 shows that light 1548a can pass
through aperture 1504a', so as to present a viewer with a lighted
image or beam having a shape that corresponds to the shape of the
aperture.
FIG. 15B-1 illustrates a toy according to embodiments of the
present invention. Toy 1500b includes a skeletal structure 1510b
having a plurality of segments 1520b. Skeletal structure 1510b
defines an open interior cavity 1530b. In some embodiments, open
interior cavity 1530b is in fluid communication with an ambient
space 1560b disposed outside of the toy. Optionally, open interior
cavity 1530b may be in fluid communication with ambient space 1560b
via a plurality of apertures 1512b defined by skeletal structure
1510b. Segments 1520b can have supports 1522b such as channels or
lumens. In some cases, one or more segments may not include a
support. Toy 1500b also includes a light assembly 1540b.
Optionally, light assembly may include a power source 1542b, such
as one or more button cell batteries, and a PC board or processor
1507b which contains a tangible medium embodying machine-readable
code for controlling activation of the light emitting elements.
Light assembly 1540b includes one or more light emitting elements
1544b that emit light 1548b. In some cases, light emitting element
1544b may include a light emitting diode (LED), an organic light
emitting diode (OLED), or the like. Similarly, light emitting
element may include a fluorescent or incandescent light. A light
emitting element may emit light radiation at any of a variety of
wavelengths. For example, a light emitting element may emit
infrared, visible, or ultraviolet light. Light assembly 1540b may
also includes one or more wires that conduct electricity between
power source 1542b and light emitting element 1544b.
Skeletal structure 1510b can present a prolate spheroid shape, such
as an American football shape. Toy 1500b can also include end caps
1503b and a logo plate 1504b which can be coupled with skeletal
structure 1510b. Toy 1500b also includes a light assembly 1540b
that can transmit light toward, onto, or through supports 1522b
such as channels or lumens. Toy 1500b may also include platform and
strut assemblies, as described elsewhere herein. As shown here,
logo plate 1504b includes a first portion 1504b' and a plurality of
second portions 1504b'', and is configured to present a shaped
outline, template, or silhouette of a logo or other graphic
element. The logo or other graphic element can represent any of a
variety of companies, brand names, groups, projects, persons,
organizations, or any other desired organization, item, devices,
process, or the like. As shown here, the combination of the first
portion and the second portions can provide a stylized type, either
alone or in conjunction with a graphic representation. Toy 1500b is
configured so that light transmitted from or emitted by various
light emitting elements can pass through first portion 1504b', or
through second portions 1504b''. In some cases, first or second
portions may include transparent or translucent materials,
optionally colored, through which light may pass. In some cases,
first or second portions may include opaque materials, through
which light may not pass. In this way, toy 1500b can present a
variety of light presentations to an toy operator or user, or to
any observer. For example, light passing through second portions
1504b'' can provide or present one or more light beams or
projections, where the shape of each light beam or projection
corresponds to the shape of the individual portion though which
that light passes, so as to present a toy operator with an image of
the word "TANGLE". Optionally, logo plate 1504b can include
supports within the body 1504b''' of the logo plate, and the
supports can transmit light in such a way that light emitted from
the body 1504b''' presents a toy operator with an inverse image of
the word "TANGLE". FIG. 15B-2 shows that light 1548b' can pass
through first portion 1504b', so as to present a viewer with a
lighted image or beam having a shape that corresponds to the shape
of first portion 1504b', and light 1548b'' can pass through second
portion 1504b'', so as to present a viewer with a lighted image or
beam having a shape that corresponds to the shape of second portion
1504b''. Light 1548b' and light 1548b'' typically differ in
intensity, color, hue, temperature, value, saturation, luminosity,
or any other light characteristic, so that a viewer can
discriminate between light passing through first portion 1504b',
and light passing through second portion 1504b''.
FIG. 15C-1 illustrates a toy according to embodiments of the
present invention. Toy 1500c includes a skeletal structure 1510c
having a plurality of segments 1520c. Skeletal structure 1510c
defines an open interior cavity 1530c. In some embodiments, open
interior cavity 1530c is in fluid communication with an ambient
space 1560c disposed outside of the toy. Optionally, open interior
cavity 1530c may be in fluid communication with ambient space 1560c
via a plurality of apertures 1512c defined by skeletal structure
1510c. Segments 1520c can have supports 1522c such as channels or
lumens. In some cases, one or more segments may not include a
support. Toy 1500c also includes a light assembly 1540c.
Optionally, light assembly may include a power source 1542c, such
as one or more button cell batteries, and a PC board or processor
1507c which contains a tangible medium embodying machine-readable
code for controlling activation of the light emitting elements.
Light assembly 1540c includes one or more light emitting elements
1544c that emit light 1548c. In some cases, light emitting element
1544c may include a light emitting diode (LED), an organic light
emitting diode (OLED), or the like. Similarly, light emitting
element may include a fluorescent or incandescent light. A light
emitting element may emit light radiation at any of a variety of
wavelengths. For example, a light emitting element may emit
infrared, visible, or ultraviolet light. Light assembly 1540c may
also includes one or more wires that conduct electricity between
power source 1542c and light emitting element 1544c.
Skeletal structure 1510c can present a prolate spheroid shape, such
as an American football shape. Toy 1500c can also include end caps
1503c and a logo plate 1504c which can be coupled with skeletal
structure 1510c. Toy 1500c also includes a light assembly 1540c
that can transmit light toward, onto, or through supports 1522c
such as channels or lumens. Toy 1500c may also include platform and
strut assemblies, as described elsewhere herein. As shown here,
logo plate 1504c includes a contour 1504c' and a plurality of
filters 1504c'', and is configured to present a shaped outline,
template, or silhouette of a logo or other graphic element. In some
cases, a filter may include transparent or translucent materials,
optionally colored, through which light may pass. In some cases, a
filter may include opaque materials, through which light may not
pass. The logo or other graphic element can represent any of a
variety of companies, brand names, groups, projects, persons,
organizations, or any other desired organization, item, devices,
process, or the like. As shown here, the combination of the contour
and filters can provide a stylized type, either alone or in
conjunction with a graphic representation. Toy 1500c is configured
so that light transmitted from or emitted by various light emitting
elements can pass through filters 1504c'', or along the edges of
contour 1504c'. In this way, toy 1500 can present a variety of
light presentations to an toy operator or user, or to any observer.
For example, light passing through filters 1504c'' can provide or
present one or more light beams, where the shape of each light beam
corresponds to the shape of the individual aperture though which
that beam passes, so as to present a toy operator with an image of
the word "TANGLE". Optionally, logo plate 1504 can include supports
within the body 1504c''' of the logo plate, and the supports can
transmit light in such a way that light emitted from the body
1504c''' presents a toy operator with an inverse image of the word
"TANGLE". In some cases, a filter 1504c'' may include a support
having lighting assembly elements contained therein. FIG. 15C-2
shows that light 1548c can pass along the edge of filter 1504c', so
as to present a viewer with an lighted image or beam having a shape
that corresponds to the inverse shape of the filter.
FIG. 16A illustrates a toy according to embodiments of the present
invention. Toy 1600a includes a skeletal structure 1610a having a
plurality of segments 1620a. Skeletal structure 16510a defines an
open interior cavity 1630a. In some embodiments, open interior
cavity 1630a is in fluid communication with an ambient space 1660a
disposed outside of the toy. Optionally, open interior cavity 1630a
may be in fluid communication with ambient space 1660a via a
plurality of apertures 1612a defined by skeletal structure 1610a.
Segments 1620a can have supports 1622a such as channels or lumens.
In some cases, one or more segments may not include a support. Toy
1600a also includes a light assembly 1640a. Optionally, light
assembly may include a power source 1642a, such as one or more
button cell batteries, and a PC board or processor 1607a which
contains a tangible medium embodying machine-readable code for
controlling activation of the light emitting elements. Light
assembly 1640a includes one or more light emitting elements 1644a
that emit light 1648a. In some cases, light emitting element 1644a
may include a light emitting diode (LED), an organic light emitting
diode (OLED), or the like. Similarly, light emitting element may
include a fluorescent or incandescent light. A light emitting
element may emit light radiation at any of a variety of
wavelengths. For example, a light emitting element may emit
infrared, visible, or ultraviolet light. Light assembly 1640a may
also includes one or more wires that conduct electricity between
power source 1642a and light emitting element 1644a.
Skeletal structure 1610a can present a spherical or geodesic shape,
such as an American soccer ball shape. Toy 1600a can also include a
logo plate or sheath 1604a which can be coupled with skeletal
structure 1610a. Toy 1600a also includes a light assembly 1640a
that can transmit light toward, onto, or through supports 1622a
such as channels or lumens. Toy 1600a may also include platform and
strut assemblies, as described elsewhere herein. As shown here,
logo plate or sheath 1604a can include any combination of contours,
apertures, portions, filters, and the like, as discussed with
regard to FIGS. 15A-15C. Optionally, toy 1600a may include a sheath
that covers all or part of a single aperture 1612a. Similarly, toy
1600a may include multiple sheaths that cover multiple apertures.
As shown in FIG. 16B, toy 1600b can include multiple sheaths, where
each aperture of the toy is covered by a sheath. Advantageously,
such logo plates, sheaths, or patches can be particularly useful as
an advertising, educational, or informational medium. They may
include solid and translucent or transparent elements, so as to
selectively allow various amounts or colors of light to transmit
through specific locations on the plate, patch, or sheath. These
elements can also include cut-outs or apertures where light can
directly pass. Relatedly, these elements can be designed to display
text or other shapes.
Skeletal structures, segments, struts, platforms, logo plates,
sheaths, and other toy elements described herein may be made of any
of a variety of materials. In some embodiments, one or more such
elements of a toy may include a durable thermoplastic resin (TPR).
For example, a toy may include a skeletal structure with a
thermoplastic resin having a durometer or hardness value of about
60. It has been discovered that toy embodiments of the present
invention provide desired bounce characteristics not found in
commonly available toy balls. Exemplary toy embodiments present
improved bounceability and resiliency profiles. Bounceability can
be characterized, for example, by how high a toy bounces, and how
many times the toy bounces, when the toy is dropped from a
distance. Resiliency can relate to how much energy is stored in the
toy when the toy deforms, and subsequently relaxes, upon bouncing.
Toy embodiments of the present invention, when dropped from a
distance, can bounce highly and for a long period of time, even
when dropped from a short distance. In some embodiments, the
incorporation of struts into a toy can enhance or modulate the
bounceability or resistance of the toy. In related embodiments, the
incorporation of logo plates, patches, or sheaths can enhance or
modulate the bounceability or resistance of the toy. In some cases,
the bounceability can be modulated by the number of plates,
patches, or sheaths on the toy, or by the hardness or elasticity of
these elements. According to some embodiments, when a ball is
dropped from a height of six feet, it bounces back to a height of
at least three feet.
According to embodiments of the present invention, interior
structural elements or support modules, such as platforms and
struts, can be flexible or depressible. In this way, these interior
platforms and struts can provide resilience or deformability to the
overall structure of the toy, and the toy structure can bounce. For
example, the toy can be thrown against or dropped upon a surface,
and spring back or rebound in a lively fashion. Often, an interior
or core support module, which may include one or more struts and
optionally one or more platforms, can be disposed within the
skeletal structure so that it resides at the center of gravity of
the toy. An interior support module may include any desired number
of struts disposed in any desired orientation. Light from a light
emitting element can be transmitted along any desired light path.
For example, light can be transmitted from a platform support
channel, through a strut support channel, and into a skeletal
segment support channel.
In some embodiments, toys may include a processor or light module
CPU that controls a light assembly of the toy. A processor or CPU
of the toy can also be configured to contain data or information
that can be emitted through small speakers in the toy. The toy may
also include positional or motion sensors, accelerometers, and the
like. The toy can include a data storage medium for storing data
from such sensors. The processor can be configured to access such
data, and to also include voice recognition processing elements.
For example, a processor can be programmed to recognize a question
spoken by the toy user, such as "Ball, how many feet did you go?"
The processor can be programmed to calculate a traveled distance,
and to emit the answer in an audible format via the speakers.
Optionally, a processor can be programmed to recognize spoken
statistical questions, and to process such questions by accessing a
statistical database. Hence, a user can ask the toy "Ball, who won
the Soccer World Cup in 1966?" and the processor controls the
speakers to emit the answer in an audible fashion.
Embodiments of the present invention provide toys with skeletal
structures and boundary envelopes having any of a variety of
shapes. For example, such shapes may include spheres, spheroids,
prolate spheroids, oblate spheroids, ellipsoids, toroids, geodesic
spheres, and the like. Toys may be shaped as any desired useful or
functional object, including without limitation bats, balls, lawn
lacrosse stick nets, bowling balls, hockey sticks and pucks, flying
discs, basketballs, basketball nets, soccer balls, soccer nets,
paddles, rackets, paddles with tethered balls, lawn darts, pool
toys, dive toys, bulls eye hoops, lariats, stationary and school
supplies, lunch pails, cups, pet toys, teething toys, toddler toys,
sandbox toys, puzzles, games, bag danglers, bag clips, drink
cozies, sandals, and the like.
Skeletal structures, light assemblies, or portions thereof may be
constructed of or include in-molded sections of any desired
material. Exemplary materials, include soft touch paint, molded
textures that match retail features such as leather patterns, glow
in the dark plastics, glitter material, scented plastics,
multi-colored plastics, metallic finishes, in mold decoration (IMD)
graphics, and the like. Skeletal structures, segments, and other
aspects of toy embodiments may include features described in U.S.
Pat. Nos. 4,509,929, 5,110,315, 6,086,445, and 7,192,328, and in
U.S. patent application Ser. Nos. 11/015,387 filed Dec. 16, 2004,
11/152,020 filed Jun. 13, 2005, and 11/558,350 filed Nov. 9, 2006.
The content of each of these filings is incorporated herein by
reference.
Toys may include auxiliary features combined with or integrated
with the skeletal structures or light assemblies. For example, a
toy can include a sound device or an internal ball or structure. In
some cases, light assemblies, sound devices, and other toy features
may be motion-activated. For example, such toy features may be
activated when the entire body of the toy is moved or translated in
any direction in three dimensions. Relatedly, such toy features may
be activated when the body of the toy is compressed or deformed.
Toys may include motions sensors that detect motion, or compression
or stress sensors that detect deformation.
In some embodiments, one or more toy segments may be coupled with
or incorporate a writing instrument or other tool, or may include a
therapeutic element or surface, as described in previously
incorporated U.S. patent application Ser. No. 11/152,020 filed Jun.
13, 2005. For example, a toy segment may include or be coupled with
a ball point pen, retractable pen, pencil, colored pencil, charcoal
pencil, mechanical pencil, fountain pen, dip pen, quill pen, paint
brush, gel pen, marker, highlighter, stylographs, crayon, and the
like. Similarly, therapeutic elements may include resilient
coatings, rotatable or slidable elements on the surface of the
segments, heating or cooling of the segments, vibratable elements,
encased gels or liquids, various textured surfaces, colors and/or
lights, varying sizes, thicknesses and/or levels of resilience,
therapeutic magnets, surfaces that move up and down or in and out,
various natural or synthetic materials, such as fabrics, leather,
features, fibers, seeds, other plants and the like, scented
materials, herbs, flavored materials, sticky surfaces, raised or
lowered images (including brail), lotions, ointments, medicines,
lubricants, sponges, porous materials, foams, rubbers, bendable
tabs, extensions, spikes, clays or putty, electrical stimulation
elements, and the like. Segments can also be configured as a holder
for a writing instrument body. In some cases, the segments can be
arranged so as to prop the writing instrument body at an angle,
disposed above the desk. Alternatively, the segments can be
arranged so as to support the writing instrument body in a
horizontal position on the desk. In related cases, the segments
will be easily removable or detachable so that if the user does not
want the segments on the toy body, he or she can simply pull them
off or otherwise disconnect them. Toy segments can be fabricated
from or include any of a variety of desired materials, such as
metals, polymers, and natural substances such as wood or bamboo.
Segments may be hollow, solid, porous, fibrous, and the like.
Segments can include a rubber coating, a rubber coating with raised
nodules, a silicone gel coating, a chemical composite coating, or a
compressible rubber coating. In some cases, the segments can
include or be coated with materials of varying hardness, including
thermoplastic rubber, synthetic rubber, and the like. Embodiments
of the present invention encompass stress relief devices,
performance balls, and pet toys. In some cases, embodiments include
baby toys for grasping and teething.
Although certain system, device, and method embodiments have been
disclosed herein, it will be apparent from the foregoing disclosure
to those skilled in the art that variations, modifications,
alternative constructions, and equivalents of such embodiments may
be made without departing from the true spirit and scope of the
invention. Therefore, the above description should not be taken as
limiting the scope of the invention which is defined by the
appended claims.
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